Co-delivery of PD-L1- and EGFR-targeting siRNAs by synthetic PEG-KL4 peptide to the lungs as potential strategy against non-small cell lung cancer.

Background: Small interfering RNA (siRNA) holds great promise for treating various lung diseases, but the lack of safe and efficient pulmonary siRNA delivery systems has hindered its advance into the clinics. The epidermal growth factor receptor (EGFR) which promotes cell proliferation, and the programmed cell death ligand 1 (PD-L1) which plays a crucial role in suppressing cytotoxic T cells activity, are two important targets for treating non-small cell lung cancer (NSCLC). Here, we explored the potential of PEG-KL4, a synthetic peptide, to deliver siRNA to various NSCLC cells and to lung tissues in mice.

Comparative evaluation of physical characteristics and volatile flavor components of subjected to hot air drying and vacuum freeze-drying.

is an economically important seaweed with Fujian characteristics. Given that its harvest is seasonal, drying is often used to remove moisture, extend storage time, and facilitate further processing. Hence, the current study sought to explore the impact of different drying processes on the quality and volatile fingerprints of To this end, the effects of hot air drying (HAD) and vacuum freeze drying (VFD) on the drying characteristics, microstructure, rehydration, and volatile components of dried were investigated.

Spray-Dried Powder Formulation of Capreomycin Designed for Inhaled Tuberculosis Therapy.

Multi-drug-resistant tuberculosis (MDR-TB) is a huge public health problem. The treatment regimen of MDR-TB requires prolonged chemotherapy with multiple drugs including second-line anti-TB agents associated with severe adverse effects. Capreomycin, a polypeptide antibiotic, is the first choice of second-line anti-TB drugs in MDR-TB therapy.

Optimization of PEGylated KL4 Peptide for siRNA Delivery with Improved Pulmonary Tolerance.

Pulmonary delivery of small interfering RNA (siRNA) is a promising therapeutic strategy for treating various respiratory diseases but an effective carrier for the delivery of siRNA into the cells of the lungs and a robust gene-silencing effect is still lacking. Previously, we reported that the KL4 peptide, a synthetic cationic peptide with a repeating KLLLL sequence, can mediate effective siRNA transfection in lung epithelial cells but its high hydrophobic leucine content, and hence poor water solubility, limits its application as a delivery vector. Here, we show that the covalent attachment of monodisperse poly(ethylene glycol) (PEG) improves the solubility of KL4 and the uptake of its complex with siRNA into lung epithelial cells, such that very robust silencing is produced.

Inhaled RNA Therapy: From Promise to Reality.

RNA-based medicine is receiving growing attention for its diverse roles and potential therapeutic capacity. The largest obstacle in its clinical translation remains identifying a safe and effective delivery system. Studies investigating RNA therapeutics in pulmonary diseases have rapidly expanded and drug administration by inhalation allows the direct delivery of RNA therapeutics to the target site of action while minimizing systemic exposure.

Intratracheal Administration of Dry Powder Formulation in Mice.

In the development of inhalable dry powder formulations, it is essential to evaluate their biological activities in preclinical animal models. This paper introduces a noninvasive method of intratracheal delivery of dry powder formulation in mice. A dry powder loading device that consists of a 200 µL gel loading pipette tip connected to an 1 mL syringe via a three-way stopcock is presented.

Modification of KL4 Peptide Revealed the Importance of Alpha-Helical Structure for Efficient siRNA Delivery.

A safe and effective delivery system is considered a key to the success of nucleic acid therapeutics. It has been reported that pulmonary surfactants or their components could facilitate the uptake of small interfering RNA (siRNA) into the lung epithelial cells. Previously, our group investigated the use of KL4 peptide, a synthetic cationic peptide that simulates the structural properties of surfactant protein B (SP-B), as siRNA delivery vector.

High siRNA loading powder for inhalation prepared by co-spray drying with human serum albumin.

The development of small interfering RNA (siRNA) formulation for pulmonary delivery is a key to the clinical translation of siRNA therapeutics for the treatment of respiratory diseases. Most inhalable siRNA powder formulations published to date were limited by the siRNA content which was often too low to be clinically relevant. This study aimed to prepare inhalable siRNA powder formulations that contained high siRNA loading of over 6% w/w by spray drying, with human serum albumin (HSA) investigated as a dispersion enhancer to improve the aerosol performance.

Effective mRNA pulmonary delivery by dry powder formulation of PEGylated synthetic KL4 peptide.

Pulmonary delivery of messenger RNA (mRNA) has considerable potential as therapy or vaccine for a range of lung diseases. Inhaled dry powder formulation of mRNA is particularly attractive as it has superior stability and dry powder inhaler is relatively easy to use. A safe and effective mRNA delivery vector as well as a suitable particle engineering method are required to produce a dry powder formulation that is respirable and mediates robust transfection in the lung.

Spray freeze drying of small nucleic acids as inhaled powder for pulmonary delivery.

The therapeutic potential of small nucleic acids such as small interfering RNA (siRNA) to treat lung diseases has been successfully demonstrated in many studies. A major barrier to their clinical application is the lack of a safe and efficient inhaled formulation. In this study, spray freeze drying was employed to prepare dry powder of small nucleic acids.

From Pulmonary Surfactant, Synthetic KL4 Peptide as Effective siRNA Delivery Vector for Pulmonary Delivery.

Pulmonary delivery of small interfering RNA (siRNA) has huge potential for the treatment of a wide range of respiratory diseases. The ability of naked siRNA to transfect cells in the lungs without a delivery vector has prompted the investigation of whether an endogenous component is at least partially responsible for the cellular uptake of siRNA, and whether a safe and efficient delivery system could be developed from this component to further improve the transfection efficiency. Surfactant protein B (SP-B), a positively charged protein molecule found in lung surfactant, is one of the possible candidates.

Inhaled powder formulation of naked siRNA using spray drying technology with l-leucine as dispersion enhancer.

Pulmonary delivery of short interfering RNA (siRNA) has been widely studied in both animal and clinical studies to treat various respiratory diseases by gene silencing through RNA interference. Some of these studies showed that the administration of naked siRNA (without the use of any delivery vectors) could achieve satisfactory gene silencing effect, a unique feature to pulmonary delivery. Liquid aerosols were mostly used with very limited studies on the use of powder aerosols for siRNA.

Delivery of RNAi Therapeutics to the Airways-From Bench to Bedside.

RNA interference (RNAi) is a potent and specific post-transcriptional gene silencing process. Since its discovery, tremendous efforts have been made to translate RNAi technology into therapeutic applications for the treatment of different human diseases including respiratory diseases, by manipulating the expression of disease-associated gene(s). Similar to other nucleic acid-based therapeutics, the major hurdle of RNAi therapy is delivery.

Incorporation of a Nuclear Localization Signal in pH Responsive LAH4-L1 Peptide Enhances Transfection and Nuclear Uptake of Plasmid DNA.

The major intracellular barriers associated with DNA delivery using nonviral vectors are inefficient endosomal/lysosomal escape and poor nuclear uptake. LAH4-L1, a pH responsive cationic amphipathic peptide, is an efficient DNA delivery vector that promotes the release of nucleic acid into cytoplasm through endosomal escape. Here we further enhance the DNA transfection efficiency of LAH4-L1 by incorporating nuclear localizing signal (NLS) to promote nuclear importation.